JP2004517598A - Uninterruptible power system - Google Patents

Abstract

The present invention relates to a combined AC-DC / DC converter. The converter (100, 300, 700, 740, 780, 800, 840, 880) selectively couples with an AC power supply (103, 303, 703, 803) having at least one phase, and at least one DC power supply. (101, 102, 301, 701, 702, 801). The converters (100, 300, 700, 740, 780, 800, 840, 880) receive power from at least one power source at a time. The converters (100, 300, 700, 740, 780, 800, 840, 880) connect the individual power supplies and the converters (100, 300, 700, 740, 780, 800, 840, 880) when switching power supplies. The pulse signal is generated by including controllable contact means for connecting or disconnecting. The converter (100, 300, 700, 740, 780, 800, 840, 880) has at least one coil (112, 113) connected to at least one DC output (125, 126, 325, 725, 726, 825). , 312). The point that the converters (100, 300, 700, 740, 780, 800, 840, 880) are superior to the prior art is that the pulse signal is divided into a plurality of periods and the power supply is supplied by a contact means during a certain period. Switching is performed. The plurality of periods alternately start with at least one first power source and at least one second power source. The current pulse from the first power supply is adjusted according to the current pulse from the second power supply. The converter includes means for adjusting the voltage of at least one DC output (125, 126, 325, 725, 726, 825). This allows flexible converters (100, 300, 700) that can be powered by one AC power supply and one or more DC power supplies (101, 102, 103, 303, 701, 702, 703, 801 and 803). , 740, 780, 800, 840, 880). Switching between the first power supply and the second power supply can be performed without a power failure. In an overload condition, current can be drawn from more than one power source.

Description

[0001]
The present invention generally relates to a combined AC-DC / DC converter (hereinafter referred to as a converter). The converter connects to an AC power supply having at least one phase and to at least one DC power supply. The converter receives power from at least one power source at a time, and the converter includes controllable switching means. The switching means connects or disconnects each power supply and the converter by switching the power supply, thereby generating a pulse signal. The converter includes at least one coil connected to at least one DC output.
[0002]
Patent application number WO 0033451 teaches a converter unit that converts one or more DC voltage levels at the input of the converter unit to one DC voltage at the output of the converter unit. The converter unit includes controllable switching means for connecting or disconnecting individual DC input voltage levels to form an oscillating signal, and the converter unit low-pass filters the oscillating signal to an output of the converter unit. A filtering means for forming a DC voltage is included.
[0003]
Unfortunately, however, this converter unit cannot be connected to an AC power supply. Also, this converter unit cannot switch power slowly without loss of power. Please refer to the description of the method below. Also, this converter unit cannot perform adaptive switching in the event of an overload condition.
[0004]
U.S. Pat. No. 5,751,564 is capable of connecting to two or more different power supplies having different voltage levels, and supplies power without a power failure even if the primary power supply is reduced or completely shut down. A switchable power supply system capable of doing so is disclosed. Its output voltage is more stable than that of the conventional switching power supply, and its internal loss is small. For this reason, the backup supply time can be extended as compared with the conventional UPS system. Finally, because the switching power supply can be directly connected to an AC power supply, for example, when used in a notebook computer, there is no need to use an AC / DC adapter when connecting to the AC power supply.
However, this circuit cannot switch between AC power and DC power without interruption.
[0005]
It is an object of the present invention to provide a converter that receives power from one or more power supplies, for example, combining an AC power supply having one or more phases and one or more DC power supplies. Switching from the first power supply to the second power supply can be performed gently without a power outage, and can rely on one or more power supplies in an overload condition.
[0006]
This can be achieved as follows. That is, the pulse signal is divided into a plurality of periods and the power supply is switched by the switching means during a certain period, and the period starts alternately from at least one first power supply and from at least one second power supply, and The current pulse from one power supply adjusts depending on the current pulse from the second power supply, and the converter includes means for adjusting the voltage of at least one DC output.
[0007]
This results in a flexible converter that can receive power from one AC power source and one or more DC power sources. Switching from the first power supply to the second power supply can be performed without power loss, and can rely on more than one power supply in an overload condition. When using an AC power supply in the form of a grid from a diesel generator and a DC power supply in the form of a battery, in a typical overload situation, the advantage of this converter is that supplementary energy is provided by the DC power supply. That is, the current from the AC power supply can be maintained at a constant high value. Thus, a small cable and a fuse can be used in the AC power supply, and the fuse does not fly due to overload.
[0008]
The term "power supply" is used herein to refer to an AC power supply having one or more phases connected via a common reference point, or connected in series via a common reference point to provide positive and negative supply voltages. Refers to one or two DC power sources that are generated.
The features of this converter are that the AC power supply is a single-phase AC power supply and that it has at least one DC power supply.
This provides a converter for a single-phase system that prevents power failures when abruptly switching between a single-phase AC power supply and one (or more) DC power supplies.
The features of this converter are that the AC power supply is a polyphase AC power supply and that it comprises at least one DC power supply.
This provides a converter for a polyphase system that prevents power failures when suddenly switching between a polyphase AC power supply and one (or more) DC power supplies.
[0009]
This converter is characterized in that, based on a signal from a current detector that measures the current passing through the coil, the control circuit connects and disconnects the first terminal of the coil and the DC power supply, respectively, Means for connecting and disconnecting the two terminals and the common reference point, respectively. When the second terminal of the coil is not connected to a common reference point, current through the coil flows to the DC output of the converter. The converter comprises means for respectively connecting and disconnecting the AC power supply and the first terminal of the coil (ie the terminal of the coil which can also be connected to a DC power supply).
[0010]
This results in a converter that has a minimal number of components and can switch the power supply slowly. Here, the first power supply is an AC power supply, and the second power supply is a DC power supply. The converter prevents a power outage when the power supply is suddenly switched.
[0011]
The features of this converter are that at least one converter is used to form a positive DC output with respect to a common reference point, and at least one converter is used to form a negative DC output with respect to a common reference point. To form a DC output.
This provides a positive (selectively more positive) DC output voltage and a negative (selectively more negative) DC output voltage, and prevents a power outage when the power supply is suddenly switched. A converter is obtained that can be prevented.
[0012]
A feature of this converter is that the converter used to create a positive output voltage with respect to a common reference point and the converter used to create a negative output voltage share an AC power source.
This results in a converter that minimizes the number of required AC power supplies. This is a great advantage, as the converter can be used where less AC power is available.
[0013]
A feature of this converter is that the means for connecting and disconnecting the first terminal of the coil and the DC power supply are controllable switches. The controllable switch can be adjusted to connect for at least a portion of every other half cycle.
Thereby, the time for supplying power from the DC power supply can be adjusted. This is associated with the advantage that multiple converters can be coupled in parallel to the same battery. In this case, each converter is assigned a different time than the other converters, during which time each converter gets its energy from the DC power source alone. The ability to couple multiple converters in parallel to the same DC power supply also means that power can be supplied using a minimum of DC power.
[0014]
A feature of this converter is that the means for connecting and disconnecting the second terminal of the coil and the common reference point, respectively, are controllable switches. The controllable switch can be adjusted to connect for at least a portion of every other half cycle. Controllable switches are generally connected in a burst series.
Thereby, the voltage of the coil can be adjusted. On the one hand, the consumption of energy from the DC power supply can be switched slowly, and on the other hand, the nominal output voltage of the converter can be adjusted in the field. The ability to adjust the converter's nominal output voltage in the field means that the same converter design can be used when multiple different output voltages are needed. Thereby, the number of different converters can be reduced.
[0015]
The characteristics of this converter are at least one of a field effect transistor, a bipolar transistor, an insulated gate bipolar transistor (IGBT), a gate turn-off thyristor (GTO), and an injection enhanced gate transistor (IEGT). The constituent semiconductor is used as a controllable switch.
This allows the choice of semiconductor technology taking into account the requirements of power supply, construction and space.
[0016]
A feature of this converter is that, in the event of an overload, the current from the AC power supply is limited to a certain maximum value, and auxiliary energy is supplied from the DC power supply.
This results in a gentler load on the AC power supply and the converter does not overload the AC power supply.
[0017]
FIG. 1 shows a single-phase coupled AC-DC / DC converter 100 having positive and negative output voltages. The positive terminal of battery 101 is connected to the anode of thyristor 106. The negative terminal of the battery 101 is connected to a common reference point 104. The cathode of thyristor 106 is connected to the cathode of diode 119. The gate of the thyristor 106 is connected to the output of the control circuit 108. The cathode of thyristor 106 is connected to coil 112. Current sensor 114 surrounds the connection point between thyristor 106 and coil 112. The current sensor 114 is connected to an input of the control circuit 108. The coil 112 is further connected to the collector of the transistor 110. The collector of the transistor 110 is connected to the anode of the diode 121. The emitters of transistors 110 are connected to a common reference point 104. The output of control circuit 108 is connected to the base of transistor 110. The cathode of diode 121 is connected to capacitor 123 and DC output 125. The capacitor 123 is further connected to the common reference point 104. The DC output 125 is connected to the control circuit 108.
[0018]
The negative terminal of battery 102 is connected to the cathode of thyristor 107. The positive terminal of the battery 102 connects to a common reference point 104. The anode of thyristor 107 is connected to the anode of diode 120. The gate of the thyristor 107 is connected to the output of the control circuit 109. The anode of the thyristor 107 is connected to the coil 113. The current sensor 115 surrounds a connection point between the thyristor 107 and the coil 113. The current sensor 115 is connected to an input of the control circuit 109. The coil 113 is further connected to the emitter of the transistor 111. The emitter of the transistor 111 is connected to the cathode of the diode 122. The collector of transistor 111 is connected to a common reference point 104. The output of the control circuit 109 is connected to the base of the transistor 111. The anode of diode 122 connects to capacitor 124 and DC output 126. The capacitors are further connected to a common reference point 104. The DC output 126 is connected to the control circuit 109.
[0019]
The anode of diode 119 connects to node 118. The cathode of diode 120 connects to node 118. Node 118 connects to switch 127. The switch 127 is further connected to the single-phase AC power supply 103 and the input of the synchronization circuit 105. The single-phase AC power supply 103 is further connected to a common reference point 104. A first output of the synchronization circuit 105 is connected to an input of the control circuit 108, a second output of the synchronization circuit 105 is connected to an input of the control circuit 109, and a third output of the synchronization circuit 105 is a control input of the switch 127. Connect to
[0020]
The role of the synchronization circuit 105 is to register when there is an AC power supply 103 of a valid voltage in order to connect the AC power supply 102 to the converter 100 via the switch 127. Another purpose of the synchronization circuit 105 is to synchronize with the AC power by providing a synchronization control signal having a known phase with respect to the AC power to the control circuits 108 and 109. In the positive half cycle of the single-phase AC power supply 103, current flows from the single-phase AC power supply 103 through the contact 127, further through the diode 119, and further through the coil 112. If transistor 110 is turned off, current flows from coil 112 through diode 121 to DC output 125. When transistor 110 is conducting, current flows from coil 112 to common reference point 104. During this period, the thyristor 106 is disconnected.
[0021]
In the negative half cycle of the single-phase AC power supply 103, the control circuit 108 causes the thyristor 106 to conduct, so that current flows from the battery 101 through the thyristor 106 and further through the coil 112. When transistor 110 is off, current flows from coil 112 to DC output 125, and when transistor 110 is conducting, current flows from coil 112 to common reference point 104. The control circuit 108 controls the transistor 110 with a variable duty cycle pulse, typically at a frequency significantly higher than the frequency of the single-phase AC power supply 103.
[0022]
The auxiliary circuit including the coil 112, the transistor 110, and the diode 121 forms a boost converter. While the transistor 110 is conducting, the current in the coil 112 increases. While the transistor is off, current begins to decrease as soon as it flows through diode 121 to DC output 125, and the voltage on coil 112 is of opposite polarity. By adjusting the duty cycle of transistor 110, the current in coil 112, and thus the voltage of DC output 125, can also be adjusted. The correct duty cycle of transistor 110 is determined by control circuit 108 based on the output voltage measured via feedback coupling from DC output 125. The capacitor 123 smoothes the voltage of the DC output 125 to a certain DC voltage. In the negative half cycle of the single-phase AC power supply 103, current flows to the single-phase AC power supply 103 from the switch 127, further from the diode 120, and further from the coil 113. When transistor 111 is shut off, current flows through coil 113 from diode 122 and further from DC output 126, and when diode 111 is conducting, current flows from reference point 104 common to coil 113. During this period, the thyristor 107 is shut off.
[0023]
In the positive half cycle of the single-phase AC power supply 103, the control circuit 109 causes the thyristor 107 to conduct, so that the current to the battery 102 flows from the thyristor 107 and further from the coil 113. When the transistor 111 is turned off, current flows from the diode 122 to the coil 113 and further from the DC output, and when the transistor 111 is conductive, current flows from the common reference point 104 to the coil 113. The control circuit 109 controls the transistor 111 with pulses of variable duty cycle, typically at a much higher frequency than the frequency of the single-phase AC power supply 103.
[0024]
The auxiliary circuit including the coil 113, the transistor 111, and the diode 122 forms a boost converter. While the transistor 111 is conducting, the current in the coil 113 increases. While transistor 111 is off, current begins to decrease as soon as it flows from diode 122 and further from DC output 126, and the voltage on coil 113 is of opposite polarity. By adjusting the duty cycle of transistor 111, the current in coil 113, and thus the voltage of DC output 126, can also be adjusted. The correct duty cycle of transistor 111 is determined by control circuit 109 based on the output voltage measured via feedback coupling from DC output 126. The capacitor 124 smoothes the voltage of the DC output to a certain DC voltage.
[0025]
The regulator consists of two independent regulators. One is for the positive output voltage in the control circuit 108 and the other is for the negative output voltage in the control circuit 109. The purpose of each regulator is to maintain a constant output voltage and to absorb current with a predetermined, well-defined curved shape whether the current is supplied from an AC or DC source. . The actual way to do this is to use two regulator loops for each of the two control circuits 108,109. One is to maintain the current curve and the other is to maintain a constant output voltage. The regulator loop that determines the current curve is usually the faster of the two regulator loops. This provides a pulse width modulated signal to one of the two transistors 110 or 111 at its output.
[0026]
Each time the transistors 110 and 111 conduct, the current in the coils 112 and 113 increases. Each time the transistors 110, 111 are turned off, the current decreases, in which case the voltages on the coils 112, 113 are of opposite polarity. In practice, this current control is performed according to various principles of keeping or changing the frequency, or according to the instantaneous value of the current or the average value averaged over several pulses. These various principles belong to the prior art, and all principles control the current in the coils 112, 113 of the converter 100 to optimally follow the amplitude and curve shape of the supplied signal. it can. To do this, the pulse / break ratio is constantly adapted by comparing the measured current with the signal corresponding to the desired voltage.
[0027]
The current in the coils 112, 113 constantly increases or decreases, but is constantly adjusted with a pulse / brake ratio to correspond to the desired curve when averaged over several pulses. As used herein, the term "pulse" refers to a control pulse for transistors 110 and 111, the frequency of which is typically higher than the frequency of the current network. The regulator loop receives a signal having a curve shape and amplitude corresponding to the current that the relevant converter 100 wants to draw at a given time. Hereinafter, this curved shape is referred to as a current reference. The shape of the current reference curve depends on the operation mode of the converter 100.
[0028]
If it is desired to draw current only from the AC power source 103, the curve shape will be the positive and negative half periods of the sine wave, respectively, and the total current drawn from the net will be sine wave. This is the curve shape seen in curve 231 of period 236 in FIG. If it is desired to draw current only from the batteries 101, 102, the only reference for both halves of the converter 100 is a DC signal. This is because in this case, it is desirable to extract a constant DC current from the batteries 101 and 102. If it is desired to draw current from both power supplies, the current reference has the form corresponding to curve 231 of period 235 in FIG. Some of this curve shape consists of half sine waves and some of rectangular or trapezoidal pulses.
[0029]
The current reference described herein may be generated as a curve of voltage or current of an electronic circuit, or may be a digitally calculated curve generated by, for example, a microprocessor or a digital signal processor (DSP). A detector circuit 105 is provided to know which mode of operation described above to perform, to determine whether the AC power supply 103 is present and has acceptable voltage quality. If this is the case, the AC operation is selected. If it is determined that the AC power supply 103 does not exist or that the current or the frequency is unacceptable for some reason, the operation is switched to battery operation. When the AC voltage recovers and is of acceptable quality, a ramp-in course, indicated by the line in FIG. 2, is performed. The detector circuit 105 can be shared by both transducers.
[0030]
Synchronization unit 105 is also used to generate the desired curve shape. It also receives and synchronizes with the AC signal. This provides the phase information to the two control / regulator units 109, 109 and informs the AC signal of the transition of a one to zero in time (eg, as a frequency between 0 and 360 degrees). Such phase information will be used later to determine the above-mentioned curved temporal course. In addition to the signals relating to the operating mode and synchronization, the amplitude of the current reference must also be able to be constantly adapted. By changing the amplitude of the signal, the amount of current drawn from the AC power supply 103 or the DC power supplies 101 and 102 changes, and thus the amount of power supplied to the converter 100 changes.
[0031]
This power supply must be constantly adapted to exactly cover the required power plus the power drawn from the output of the converter 100 and the power due to losses. If power is supplied more than necessary, it means that the voltage of the capacitors 123 and 124 continues to increase, and correspondingly, if the supplied power is too small, the voltage decreases. Thus, to maintain the correct output voltage, a regulator loop is provided in each control / regulator circuit 108, 190, and the voltages at 125 and 126 are measured and compared to the appropriate reference values. If the output voltage deviates from the desired value, the amplitude of the current reference signal described above is adjusted upward or downward.
[0032]
There is always only one specific maximum value of the current allowed to be drawn from the AC power source 103. During the ramp-in course, the maximum value is increased linearly from zero to a predetermined maximum value within a predetermined time (for example, 10 seconds). If it is desired to supply more current or power than this maximum allowable value, a half-wave sine signal having the maximum possible value is formed, while the remaining required power is supplemented by current pulses from the battery. The distribution of the two pulses is constantly calculated to cover the total required power supply. Correspondingly, this limitation of the AC current pulse is used to limit the current from the overloaded current network or diesel generator. Also, in this case, the amount of replenishment from the battery required to supply the required total power is calculated.
[0033]
Decoupled at node 118, instead connecting AC power supply 103 and switch 127 to the AC input of the rectifier bridge, connecting the positive output of the rectifier bridge to the anode of diode 119, and connecting the negative output of the rectifier bridge to diode 120. When connected to the cathode, power can also be supplied to the positive and negative halves of converter 100 from AC power supply 103 in both half periods. Thereby, the power consumption of the batteries 101 and 102 can be reduced.
[0034]
FIG. 2 shows the curve of the ramp-in course of the single-phase coupled AC-DC / DC converter 100 with positive and negative output voltages. The first curve 231 shows the current through the coil 112. The second curve 232 shows the current through the coil 113. The third curve 233 shows the total current of the single-phase AC power supply 103. In the first curve 231, the second curve 232, and the third curve 233, the first period 234 indicates power supply from only the batteries 101 and 102, and the second period 235 indicates that the batteries 101 and 102 and the single-phase AC 4 shows a ramp-in course supplied with power from the power supply 103. The current from batteries 101 and 102 decreases as the current from single-phase AC power supply 103 increases. The third period 236 indicates power supply from only the single-phase AC power supply 103.
[0035]
In period 234, only batteries 101 and 102 power coupled AC-DC / DC converter 100. In the period 235, a ramp-in course occurs, and power is supplied not only from the batteries 101 and 102 but also from the single-phase AC power supply 103. The intensity of the pulse current from the batteries 101 and 102 decreases as the pulse current from the single-phase AC power supply 103 increases. In the period 236, only the single-phase AC power supply 103 supplies power to the combined AC-DC / DC converter 100.
[0036]
FIG. 3 shows a single-phase coupled AC-DC / DC converter 300 having a positive output voltage. The positive terminal of battery 301 connects to the anode of thyristor 306. The negative terminal of battery 301 is connected to the anode of thyristor 306. The negative terminal of the battery 301 is connected to a common reference point 304. The cathode of thyristor 306 is connected to the cathode of diode 319. The gate of thyristor 306 connects to the output of control circuit 308. The cathode of thyristor 306 connects to coil 312. The current sensor 314 surrounds a connection point between the thyristor 306 and the coil 312. The current sensor 314 connects to the input of the control circuit 308. The coil 312 is further connected to the collector of the transistor 310. The collector of transistor 310 is connected to the anode of diode 321. The emitters of transistors 310 are connected to a common reference point 304.
[0037]
The output of control circuit 308 is connected to the base of transistor 310. The cathode of diode 321 is connected to capacitor 323 and DC output 325. Capacitor 323 is further connected to common reference point 304. DC output 325 is connected to control circuit 308. The anode of diode 319 is further connected to switch 327. The switch 327 is further connected to the single-phase AC power source 303 and the input of the synchronization circuit 305. The single-phase AC power supply 303 is further connected to a common reference point 304. A first output of the synchronization circuit 305 is connected to an input of the control circuit 308, and a second output of the synchronization circuit 305 is connected to a control input of the switch 327.
[0038]
An indication of the functionality of the single-phase coupled AC-DC / DC converter 300 with a positive output voltage according to FIG. 3 is shown in FIG. 1 with a single-phase coupled AC-DC / DC with positive and negative output voltages. Follow the indication of the functionality of the converter half 100. As with the single-phase combined AC-DC / DC converter 100 with positive and negative output voltages, the AC power source 303 and switch 327 are instead coupled to the AC input of the rectifier bridge, and the positive output of the rectifier bridge is connected to a diode. The negative output of the rectifier bridge may be connected to the reference point 304. Thus, power can be supplied from AC power supply 303 to converter 300 in both half cycles. Thereby, the power consumption of the battery 301 can be reduced.
[0039]
FIG. 4 shows the ramp-in-course curves of a three-phase coupled AC-DC / DC converter 700, 740, 780 with positive and negative output voltages. The first curve 431 shows the current through the positive half coil of the converter in one phase (phase 1). The second curve 432 shows the current through the negative half coil of the converter in the same phase (Phase 1). The third curve 433 shows the total current of the AC power supply 703 in the same phase (phase 1). The fourth curve 437 shows the total current from the battery 701 to the positive half of the converter in all three phases (Phase 1, Phase 2, Phase 3). The fifth curve 438 shows the total current from the negative half of the converter to the battery 702 in all three phases (phase 1, phase 2, phase 3). In the first curve 431, the second curve 432, the third curve 433, the fourth curve 437, and the fifth curve 438, the first period 434 is when power is supplied only from the batteries 701 and 702. The second period 435 indicates a ramp-in course in which power is supplied from the batteries 701 and 702 and the AC power supply 703. The current from batteries 701 and 702 decreases as the current from AC power supply 703 increases. A third period 436 indicates power supply from only the AC power supply 703.
[0040]
An illustration of the functionality of the ramp-in-course of the three-phase coupled AC-DC / DC converters 700, 740, 780 with positive and negative output voltages according to FIG. 4 is shown in FIG. Follow the indication of the ramp-in-course functionality of the single-phase coupled AC-DC / DC converter 100 with voltage. The batteries 701 and 702 are shared by (same as) the converters 700, 740 and 780 of all three phases (phase 1, phase 2 and phase 3). The batteries 701, 702 are three otherwise independent circuits 700, 740, 780, each corresponding to the single-phase coupled AC-DC / DC converter 100 with positive and negative output voltages according to FIG. Power. This means that the battery 701 connects to three thyristors in each of the circuits 700, 740, 780, and the battery 702 connects to three thyristors in each of the same three circuits. The three circuits 700, 740, 780 use respective phases, and the common reference point 704 is shared by the three phases.
[0041]
FIG. 5 shows the curve of the overload course of the single-phase coupled AC-DC / DC converter 100 with positive and negative output voltages. The first curve 539 shows the current load for the allowable upper current threshold in percentage. The second curve 531 shows the current through the coil 112. The third curve 532 shows the current through the coil 113. The fourth curve 533 indicates the total amount of current of the single-phase AC power supply 103. In the first curve 539, the second curve 531, the third curve 532, and the fourth curve 533, the first and third periods 536 are normal operation by power supply from only the single-phase AC power supply 103. And the second period 540 indicates an overload course due to power supply from both the batteries 101 and 102 and the single-phase AC power supply 103. The amplitude of the current from batteries 101 and 102 is the amplitude when the current from single-phase AC power supply 103 is kept constant and within a certain allowable current threshold.
[0042]
In two periods 536, a normal operation is performed. In this case, only the single-phase AC power supply 103 supplies power to the combined AC-DC / DC converter 100. In the period 540, an overload course occurs, and power is supplied from both the batteries 101 and 102 and the single-phase AC power supply 103. The amplitude of the pulse current from the batteries 101, 102 is adjusted to completely compensate for overload. This keeps the current from single-phase AC power supply 103 constant and within a certain allowable threshold.
[0043]
FIG. 6 shows the curves of the overload course of a three-phase coupled AC-DC / DC converter 700, 740, 780 with positive and negative output voltages. The first curve 639 shows the overload of all three phases as a percentage against the allowable upper current threshold. The second curve 631 shows the current through the coil in the positive half of the converter in one phase (phase 1). The third curve 632 shows the current through the coil in the negative half of the converter in the same phase (Phase 1). The fourth curve 633 shows the total current of the AC power supply 703 in the same phase (phase 1). A fifth curve 637 shows the total current from the positive half battery 701 of the converter to all three phases (phase 1, phase 2, phase 3). A sixth curve 638 shows the total current from all three phases (phase 1, phase 2, phase 3) to battery 702 in the negative half of the converter. In the first curve 639, the second curve 631, the third curve 632, and the fourth curve 633, the first and third periods 636 indicate a normal operation by power supply from only the AC power supply 703. , A second period 640 indicates an overload course due to power supply from both the batteries 701 and 702 and the AC power supply 703. The amplitude of the current from batteries 701 and 702 is the amplitude when the current from AC power supply 703 is kept constant and within a predetermined allowable current threshold.
[0044]
An indication of the functionality of the overload course of the three-phase coupled AC-DC / DC converters 700, 740, 780 with positive and negative output voltages according to FIG. 6 is shown in FIG. According to the indication of the functionality of the overload course of the single-phase coupled AC-DC / DC converter 100 having The batteries 701 and 702 are shared by (same as) the converters 700, 740 and 780 of all three phases (phase 1, phase 2 and phase 3). The batteries 701, 702 are three otherwise independent circuits 700, 740, 780, each corresponding to the single-phase coupled AC-DC / DC converter 100 with positive and negative output voltages according to FIG. Power. This means that the battery 701 connects to three thyristors in each of the circuits 700, 740, 780, and the battery 702 connects to three thyristors in each of the same three circuits. The three circuits 700, 740, 780 use respective phases, and the common reference point 704 is shared by the three phases.
[0045]
FIG. 7 shows a three-phase coupled AC-DC / DC converter with positive and negative output voltages, built with three converters 700, 740, 780 with shared DC power supplies 701, 702. The positive terminal of battery 701 connects to the anode of the thyristor in each of the three converters 700, 740, 780, corresponding to thyristor 106 of FIG. The negative terminal of the battery 701 is connected to a common reference point 704. The negative terminal of battery 702 connects to the thyristor cathode in each of the three converters 700, 740, 780, corresponding to thyristor 107 of FIG. The positive terminal of the battery 702 connects to a common reference point 704. The switches in each of the three converters 700, 740, 780, corresponding to the switch 127 in FIG. 1, are connected to each phase of the AC power supply 703. The AC power supply 703 is further connected to a common reference point 704. The positive outputs of the three converters 700, 740, 780 all connect to output 725. The negative outputs of the three converters 700, 740, 780 all connect to output 726. The references of the three transducers 700, 740, 780 connect to a reference point 704.
[0046]
An indication of the functionality of a three-phase coupled AC-DC / DC converter with positive and negative output voltages constructed with three converters 700, 740, 780 with shared DC power supplies 701, 702 according to FIG. 1 follows the indication of the functionality of the single-phase coupled AC-DC / DC converter 100 with positive and negative output voltages according to FIG.
[0047]
FIG. 8 shows a three-phase coupled AC-DC / DC converter with a positive output voltage, constructed with three converters 800, 840, 880 having a shared DC power supply 801. The positive terminal of battery 801 connects to the anode of the thyristor in each of the three converters 800, 840, 880, corresponding to thyristor 306 of FIG. The negative terminal of the battery 801 is connected to a common reference point 804. The switches in each of the three converters 800, 840, 880 corresponding to the switches 327 in FIG. 3 connect to each phase of the AC power supply 803. The AC power supply 803 is further connected to a common reference point 804. The negative outputs of the three converters 800, 840, 880 all connect to output 825. The references of the three transducers 800, 840, 880 all connect to a reference point 804.
[0048]
A representation of the functionality of a three-phase coupled AC-DC / DC converter with positive and negative output voltages, constructed with three-phase converters 800, 840, 880 with a common DC power supply 801 according to FIG. 1 according to the indication of the positive half functionality of the single-phase coupled AC-DC / DC converter 100 with positive and negative output voltages.
[0049]
The converter (100, 300, 700, 740, 780, 800, 840, 880) features, for example, a predetermined load (typically a full load) on at least one DC output (125, 126, 325, 725, 726, 825). ), The switching from the DC power supply (101, 102, 301, 701, 702, 801) to the AC power supply (103, 303, 703, 803) (generally a diesel generator) is performed adaptively, and This is to take into account the frequency and voltage stability of the power supplies (103, 303, 703, 803). Such adaptive switching of the power supply causes a gradual switch from the DC power supply to the AC power supply, and power is supplied from both power supplies during the switching. Adaptive switching of the power supplies optionally includes supplying power from both power supplies for a plurality of consecutive periods. Finally, adaptively switching the power supply means that it is possible to switch back completely or partially to the original DC power supply. This allows for a more gradual coupling with the AC power supply and does not force the converter and load to abruptly couple the AC power supply. This prevents the frequency and voltage of the AC power supply from fluctuating due to overload. If the AC power source is a diesel generator, it is important to avoid suddenly forcing the load into the load. This is because if an overload occurs, a rotor current is generated and the frequency and voltage of the diesel generator become unstable. In the worst case, self-oscillation may occur due to instability, resulting in a power outage.
[0050]
The converter (100, 300, 700, 740, 780, 800, 840, 880) is characterized by the dynamic load change when power is supplied from an AC power supply (103, 303, 703, 803) (generally a diesel generator). And adaptively increasing the current from at least one DC output (125, 126, 325, 725, 726, 825). When adaptively compensating for a dynamic load change, supplementary energy is obtained from the DC power supply (101, 102, 301, 701, 702, 801) to obtain the AC power supply (103, 303, 703, 803). The frequency and voltage stability should be considered appropriately. When adaptively compensating for dynamic load changes in this way, an auxiliary power supply is provided from the DC power supply, and (for a certain period of time) power is supplied from both power supplies. Optionally, power from both power sources may be provided for a plurality of consecutive periods. This causes the load to be applied more slowly to the AC power supply, and the converter does not forcibly couple the AC power supply to the load. This prevents the frequency and voltage of the AC power supply from fluctuating due to overload. If the AC power source is a diesel generator, it is important to avoid suddenly forcing the load into connection. This is because overloading causes rotor currents, which cause the frequency and voltage of the diesel generator to become unstable, and in the worst case self-oscillations due to instability can result in a power outage. .
[Brief description of the drawings]
The present invention will be described in detail with reference to the accompanying drawings.
FIG.
1 shows a single-phase coupled AC-DC / DC converter with positive and negative output voltages.
FIG. 2
3 shows a ramp-in-course curve for a single-phase coupled AC-DC / DC converter with positive and negative output voltages.
FIG. 3
1 shows a single-phase coupled AC-DC / DC converter with a positive output voltage.
FIG. 4
3 shows a ramp-in-course curve for a three-phase coupled AC-DC / DC converter with positive and negative output voltages.
FIG. 5
Figure 4 shows the curves of the overload course of a single-phase coupled AC-DC / DC converter with positive and negative output voltages.
FIG. 6
3 shows the curves of the overload course of a three-phase coupled AC-DC / DC converter with positive and negative output voltages.
FIG. 7
3 shows a three-phase coupled AC-DC / DC converter with positive and negative output voltages, consisting of three converters with a shared DC power supply.
FIG. 8
3 shows a three-phase coupled AC-DC / DC converter with a positive output voltage, consisting of three converters with a shared DC power supply.

Claims (10)

A converter selectively coupled to an AC power supply having at least one phase (103, 303, 703, 803) and selectively coupled to at least one DC power supply (101, 102, 301, 701, 702, 801). (100, 300, 700, 740, 780, 800, 840, 880), wherein the converter (100, 300, 700, 740, 780, 800, 840, 880) is powered by at least one power source at a time. The converters (100, 300, 700, 740, 780, 800, 840, 880) receive individual power supplies and the converters (100, 300, 700, 740, 780, 800, 840, 880) to generate a pulse signal by including a controllable contact means for connecting or disconnecting said converter (100, 30). , 700, 740, 780, 800, 840, 880) includes at least one coil (112, 113, 312) for connecting to at least one DC output (125, 126, 325, 725, 726, 825). The feature is that the pulse signal is divided into a plurality of periods and the power is switched by the contact means during a certain period, and the period is switched from at least one first power source and at least one second power source during the period. Starting, the current pulse from the first power supply adjusts according to the current pulse from the second power supply, and the converter outputs at least one DC output (125, 126, 325, 725, 726, 825). A converter (100, 300, 700, 740, 780, 800, 840, 880), which comprises means for regulating the voltage. The converter (100, 300) according to claim 1, characterized in that the AC power supply (103, 303) is a single-phase AC power supply and is provided with at least one DC power supply (101, 102, 310). ). The converter (700, 740) according to claim 1, characterized in that the AC power supply (703, 803) is a polyphase AC power supply and comprises at least one DC power supply (701, 702, 801). , 780, 800, 840, 880). Based on a signal from a current detector (114, 115, 314) for measuring a current passing through the coil (112, 113, 312), a control circuit (108, 109, 308) controls the coil (112, 113, 312). Means for connecting and disconnecting the second terminal of the coil and the DC power supply (101, 102, 301, 701, 702, 801), respectively, and a common reference point (2) for the second terminal of the coil (112, 113, 312). 104, 304, 704, and 804), and the second terminal of the coil (112, 113, 312) has a common reference point (104, 304, 704, 804). When not connected to the converter, the current passing through the coil (112, 113, 312) is converted into the current by the converter (100, 300, 700, 740, 780, 800, 8). 0,880) to the DC output (125, 126, 325, 725, 726, 825) and the converter (100, 300, 700, 740, 780, 800, 840, 880) is connected to an AC power source (103 , 303, 703, 803) and means for connecting and disconnecting the first terminals of the coils (112, 113, 312), respectively. The described converter (100, 300, 700, 740, 780, 800, 840, 880). A positive DC output (125, 725) is formed with respect to a common reference point (104, 704) using at least one transducer (300) and a common reference point (125) using at least one transducer. A converter (100, 700, 740, 780) according to at least one of the preceding claims, characterized in that a negative DC output (126, 726) is formed with respect to (104, 704). A converter (300) used to form a positive output voltage with respect to a common reference point (104, 704) and a converter used to form a negative output voltage are the AC power sources (103, 703). The converter (100, 700, 740, 780) according to claim 5, characterized in that: Means for connecting and disconnecting the first terminal of the coil (112, 113, 312) and the DC power supply (101, 102, 301, 701, 702, 801) respectively are controllable switches (106, 107, 306). 7. At least one of the claims 4-6, characterized in that the controllable switches (106, 107, 306) are adjustable to connect during at least part of every other half-period. (100, 300, 700, 740, 780, 800, 840, 880). The means for connecting and disconnecting the second terminals of the coils (112, 113, 312) and the common reference points (104, 304, 704, 804) respectively are controllable switches (110, 111, 310). And said controllable switches (110, 111, 310) can be adjusted to connect for at least a portion of every other half-period, and said controllable switches (110, 111, 310) Transformer (100, 300, 700, 740, 780, 800, 840, 880) according to at least one of claims 4 to 7, characterized in that they are generally connected in a burst series. A semiconductor comprising at least one of a field effect transistor, a bipolar transistor, an insulated gate bipolar transistor (IGBT), a gate turn-off thyristor (GTO), and an injection enhanced gate transistor (IEGT) can be controlled. The converter (100, 300, 700, 740, 780, 800, 840) according to at least one of the claims 4 to 8, characterized in that it is used as a switch (106, 107, 110, 111, 306, 310). , 880). In an overload state, the current from the AC power supply (103, 303, 703, 803) is limited to a certain maximum value, and auxiliary energy is supplied to the DC power supply (101, 102, 301, 701, 702, 801). 10. A converter (100, 300, 700, 740, 780, 800, 840, 880) according to at least one of the claims 1 to 9, characterized in that it is supplied from a converter.